ABB Modures LZ91 Instructions For Installation And Operation Manual

Type
Instructions For Installation And Operation Manual

This manual is also suitable for

ASEA BROWN BOVERI
CH-ES 83-92.10 E
Edition May
1991
modures®
Static Distance Relays
Types
L291
, L292, LZ92-1
Instructions for Installation
and
Operation
@1986ABB
Relays AG
Baden/Switzerland
4th edition
All rights with respect
to
this document, including applications for patent and registration
of
other industrial property rights, are reserved. Unauthorised use, in particular reproduc-
tion
or
making available
to
third parties,
is
prohibited.
This document has been carefully prepared and reviewed, however should in spite
of
this
the reader find an error, he is requested
to
inform us at his earliest convenience.
The data contained herein purports solely
to
describe the product and is not a warranty of
performance
or
characteristics. It is with the best interests of our customers in mind that
we constantly strive
to
improve
our
products and keep them abreast
of
advances in
technology. This may, however, lead
to
discrepancies between a product and its "Tech-
nical Description"
or
"Instructions
for
Installation and Operation".
C 0 N T E N T S
1.
2.
3.
3.1
3.1.1
3
.1.
2
3.1.3
3.2
3.2.1
3.2.2
3.3
3.4
3.4.1
3.4.2
3.5
3.6
3.7
3.8
3.9
3.10
3
.11
3.12
4.
5.
5.1
5.2
5.3
5.4
5.5
5.6
5.7
6.
6.1
6.2
6.3
6.4
6.5
6.6
6.7
7.
7.1
8.
9.
APPLICATION
MECHANICAL
DESIGN
DETERMINING
THE
SETTINGS
Selecting
the
operating
mode
Distance
relay
LZ91
Distance
relay
LZ92
Distance
relay
LZ92-l
Setting
the
starting
units
Overcurrent
starting
Underimpedance
starting
k
factor
for
the
distance
measuring
system
Igpedance
settings
of
the
various
zones
Determining
the
reaches
of
the
distance
zones
Determining
the
settings
m.
and
N.
J_
1.
Arc
resistance
compensation
Direction
of
measurement
Zone
4
Time
step
characteristic
Symbols
and
significance
of
the
switches
on
the
main
processing
unit
Main
processing
unit
equipped
for
intertripping
schemes
Frontplate
signals
Versions
of
the
input
transformer
and
main
processing
units
CHECKING
THE
SHIPMENT
INSTALLATION
AND
WIRING
Relay
location
and
ambient
conditions
Checking
the
wiring
C.t.
connections
P.t.
connections
Auxiliary
supply
Loading
of
tripping
and
signalling
contacts
Opto-coupler
inputs
COMMISSIONING
Checking
the
setting
prior
to
commissioning
Inserting
the
relay
and
switching
on
the
auxiliary
supply
Test
points
on
the
unit
EW91
Checking
the
load
voltages
and
currents
Testing
the
distance
relay
using
the
test
buttons
Testing
the
distance
relay
using
a
test
set
Instructions
for
modifying
relay
operation
OPERATION
AND
MAINTENANCE
Ancillaries
and~ares
TROUBLE-SHOOTING
APPENDICIES
Page
3
3
5
5
5
5
5
6
6
7
14
15
15
16
21
21
22
23
23
24
25
25
26
27
27
27
27
28
29
29
29
30
30
30
30
31
32
37
37
38
38
39
40
1
List
of
abreviations
and
symbols
I
Bmax
U,1
z.
1
Index
i
Index
p
Index
s
2
phase
currents
neutral
current
load
current
max.
load
current
possible
balancing
current
rated
current
fault
current
phase-to-neutral
voltages
ratio
of
zero
to
positive-sequence
impedances
(neutral
current
factor)
phase-angle
of
line
difference
voltage
(difference
between
fault
voltage
and
replica
impedance
voltage)
sum
voltage
(sum
of
fault
voltage
and
replica
impedance
voltage)
forwards
resp.
reverse
replica
reactances
of
the
underimpedance
starters
of
LZ92
or
LZ92-l
reactance
of
line
impedance
of
zone
i
positive-sequence
impedance
of
line
zero-sequence
impedance
of
line
zone
No.
primary
values
secondary
values
1.
APPLICATION
The
solid-state
distance
relays
LZ91, LZ92
and
LZ92-l
have
been
designed
for
high-speed
discriminative
protection
applications,
primarily
in
medium-voltage
systems.
They
are
equally
suitable
for
cable
and
overhead
line
circuits
and
the
power
systems
may
be
ungrounded,
impedance
or
solidly
grounded.
When
protecting
extremely
short
lines,
the
distance
relays
are
already
equipped
with
the
logic
to
operate
in
a
directional
comparison
scheme
(permissive
over-
reaching
transfer
tripping)
with
pilot
wires.
The
corresponding
pilot
wire
ancillaries
have
the
type
designations
ER91
and
NR91.
The
relays
are
also
prepared
for
operating
in
conjunction
with
an
auto-reclosure
relay
(e.g.
type
WT91
for
three-phase
reclosure).
All
the
relays
are
of
the
switched
type,
having
starting
units
(fault
detectors)
which
apply
the
correct
fault
quantities
to
a
single
direction
and
distance
determining
measuring
system.
The
starting
units
of
the
LZ91
operate
on
overcur-
rent,
so
that
the
relay
is
simpler
and
more
economical,
but
can
only
be
applied
in
systems
in
which
the
lowest
fault
current
is
clearly
greater
than
the
maximum
load
current.
Both
the
LZ92
and
the
LZ92-l
are
equipped
with
true
underimpedance
uni
ts
(not
just
voltage-controlled
overcurrent)
and
are
thus
capable
of
detec-
ting
weak
faults
at
times
of
low
generation
with
fault
currents
below
the
maximum
load
currents
at
peak
periods.
A
full
description
of
their
operation
is
contained
in
publication
CH-ES
23-92.lOE
"Solid-state
distance
relays
types
LZ91, LZ92
and
LZ92-l"
and
their
technical
data
is
given
in
data
Sheet
CH-ES
63-92.10
E.
2.
MECHANICAL
DESIGN
The
various
plug-in
units
which
make
up
the
relays
are
accommodated
in
standard
19"
electronic
equipment
racks,
and
these
in
turn
are
either
grouped
together
with
other
relays
in
cubicles,
or
fitted
into
casings
for
surface
or
semiflush
switchpanel
mounting.
The
corresponding
dimensioned
drawings
are
in
the
appendi-
ces
to
these
instructions.
The
plug-in
units
have
a
standard
height
of
3,5
U
(U
=
44.45
mm)
and
varying
widths
given
as
a number
of
divisions
T
(T
= 17 mm). One
19"
rack
has
space
for
plug-in
units
adding
up
to
a maximum
of
24
T.
The
standard
versions
of
the
distance
relays
LZ91, LZ92
and
LZ92-l
only
require
20
T,
which
is
less
than
one
full
rack.
The
distance
relays
comprise
the
following
plug-in
units:
-
input
transformer
unit
type
EW91,
width
6
T,
also
containing
signal
conditio-
ning
circuits,
measuring
sockets
and
auxiliary
tripping
relay.
-
main
processing
unit:
KI91
for
LZ91,
KZ91
for
LZ92
or
KZ91-l
for
LZ92-l.
The
terminals
of
the
main
processing
units
are
compatible
and
they
have
the
same
width.
3
4
-
signalling
unit
AV91
and/or
AV94
(1
T)
-
auxiliary
supply
unit
NF92 (3
T),
a
DC/DC
converter
for
generating
the
inter-
nal
relay
supply
voltages.
-
test
socket
connector
XX91
(option)
(3
T)
.
-
auto-reclosure
relay
WT91
(option)
(4
T).
-
pilot
wire
units
ER91
and
NR91
(option)
(4
Teach).
'rhese
instructions
apply
to
the
basic
versions
of
the
distance
relays,
i.e.
relays
equipped
with
EW91
and
either
KI91,
KZ91
or
KZ91-1
and
also
an
auxiliary
supply
unit.
There
are
two
versions
of
the
input
transformer
and
main
processing
units
available,
which
have
resulted
from
further
technical
develop-
ment
and
which
are
described
in
these
instructions
(see
Section
3.12).
3.
DETERMINING
THE
SETTINGS
All
important
settings
on
the
distance
relays
LZ91, LZ92
and
I,Z92-1
are
thumb-
wheel
switches.
The
corresponding
setting
formulas
are
printed
on
the
frontplate
(see
Figures
9.3
to
9.8).
In
each
case
the
setting
in
the
correct
dimensions
is
obtained
by
inserting
the
number
indicated
on
the
thumbwheel
switches
in
the
formula
and
working
it
out.
The
settings
themselves
(e.g.
impedance
of
the
under
impedance
starting
uni
ts)
are
printed
in
italics.
Settings
which
are
normally
only
made
once
during
commissioning
are
miniature
switches
located
on
the
PCB's.
Information
relating
to
these
settings
is
marked
on
the
frontplate
of
the
KI91,
KZ91
respectively
KZ91-l
behind
the
hinged
flap
of
the
equipment
rack
(Figures
9.
3
to
9.
8) . A
symbol
shows
on
which
PCB
the
particular
functional
switch
is
to
be
found.
The
PCB's
in
the
units
KI91,
KZ91
respectively
KZ91-1
are
numbered
from
left
to
right
seen
from
the
front
and
as
marked
on
the
frontplate.
(There
is
no
PCB
3
in
KI91.)
Further
information
on
this
can
be
found
in
Section
3.9.
3.1
Selecting
the
operating
mode
3.1.1
Distance
relay
LZ91
A
choice
can
be
made
between
two
operating
modes
using
miniature
switch
1
on
PCB
1
of
unit
KI91
(Fig.
9.21):
Mode
A
Mode L
for
solidly
grounded
systems,
i.e.
earth
faults
have
to
be
tripped.
for
ungrounded
or
impedance
grounded
systems,
but
only
with
acyclical
phase-preference
for
cross-country
faults.
3.1.2
Distance
relay
LZ92
As
with
the
distance
relay
LZ91, a
choice
can
be
made
between
the
modes A
and
L
using
miniature
switch
1
on
PCB
1
of
unit
KZ91.
In
this
case,
however,
mode
1::::,
also
permits
cyclical
(LO
in
the
code)
as
well
as
acyclical
(Ll
in
the
code)
phase-preference
for
cross-country
faults.
This
change
is
made
by
appro-
priately
positioning
soldered
link
LB7
on
PCB
1
(see
Fig.
9.22).
Standard
phase-preferences
are
R
before
T
before
S
(acyclically)
respectively
R
before
T,
T
before
S,
S
before
T
(cyclically).
3.1.3
Distance
relay
LZ92-l
In
solidly
grounded
systems
in
which
it
is
essential
that
earth
faults
be
tripped
mode
j;-
should
be
set.
In
ungrounded
or
impedance
grounded
systems
the
same
phase-preference
must
be
set
as
is
used
in
the
rest
of
the
system.
5
The
operating
mode
is
set
on
the
main
processing
unit
KZ91-1
with
the
aid
of
switch
1
(Fig.
9.23).
This
switch
has
four
sections
which
have
to
be
set
in
accordance
with
Table
3
.1.
'l'he same
information
is
printed
on
the
frontplate
behind
the
withdrawing
handle
(Fig.
9.8).
switch
section
*
Mode
-
No.
1
No. 2 No.
3 No.
4
Phase
preference
Setting
OFF
ON
ON
OFF
grounded
systems
±
OFF
OFF
ON
OFF
R'rS
acyclically
RTS
acyc.
ON
ON
OFF OFF
RTSR
cyclically
R'l'SR
eye.
OFF
ON
OFF OFF
TRS
acyclically
TRS
acyc.
ON
OFF
OFF OFF
TRS'l'
cyclically
TRST
eye.
ON
OFF
ON
OFF
TSR
acyclically
TSR
acyc.
ON ON
ON
ON
RST
acyclically
RST
acyc.
OFF
OFF OFF
OFF
STR
acyc
lie
ally
**
STR
acyc.
OFF
OFF OFF
ON
SRT
a<:Y_<:l_i_~~l
_
_1-y
**
SRT
acyc.
*
In
position
"ON"
the
white
lever
is
toward
the
PCB.
**
Only
for
units
with
the
designation
"AEND.
:B"
on
PCB
1.
Table
3.1
-
Positions
of
the
switch
sections
of
switch
1
on
PCB
1
of
unit
KZ91-1
in
relation
to
operating
mode
3.2
Setting
the
starting
units
3.2.1
Overcurrent
starting
6
The
pick-up
setting
of
the
overcurrent
uni
ts
must
be
at
the
very
least
so
high
that
it
cannot
be
reached
by
the
maximum
current
in
healthy
phases.
The
following
must
be
taken
into
account
when
calculating
this
current:
-
In
the
case
of
double-circuit
lines
the
load
current
can
briefly
double
when
one
line
is
tripped.
-
An
additional
balancing
current
IA
can
flow
in
the
healthy
phases
during
earth
faults.
A
relay
which
has
picked
up
must
also
be
able
to
reset
at
the
level
of
the
maximum
load
current
I
after
a
fault
has
been
tripped
in
the
first
zone
Bmax
.
of
another
relay.
Taking
the
reset
ratio
and
accuracy
of
the
relay
into
account,
the
lowest
permissible
setting
is
given
by:
lr;max
+~I
~~~~~~~-
+
0.06
The
maximum
pe.rmissible
setting
(I/I
)
is
calculated
from
the
minimum
fault
current
IK
for
a
fault
at
the
rerWo.r~xend
of
the
next
section
of
line.
(
Should
(I
/I
) .
be
less
than
(I/I
) .
according
to
the
above
relationship,
then
a
re!ayNwTtR
underimpendance
sW.a~E~ng,
e.g.
LZ92
or
LZ92-l,
must
be
used
instead
of
a
distance
relay
LZ91.
When
used
in
ungrounded
or
impedance
grounded
systems
(mode
L.
) ,
the
current
measuring
elements
of
unit
KI91
are
connected
to
R,
T
and
E.
The
sensitivity
of
the
neutral
element
in
the
standard
versions
is
twice
that
of
the
phase
elements
(I,r/IPh
=
0.5,
I/
•••
/
in
the
code
of
the
KI91).
If
some
other
sensitivity
is
specified,
it
can
be
seen
from
the
relay
ordering
code:
If
...
/sensitivity
factor
Should
it
be
impossible
to
set
the
phase
elements
such
that
they
pick
up
reliably
at
the
lowest
phase
fault
level,
but
do
not
pick
up
at
the
maximum
earth
fault
current,
then
a
distance
relay
LZ92
or
LZ92-1
must
be
used.
3.2.2
Underimpedance
starting
The
following
two
frontplate
(KZ91
or
KZ91-l)
settings
apply
to
the
underimpe-
dance
starting
units:
-
the
pick-up
of
the
neutral
current
element
-
the
reach
of
the
underimpedance
elements.
3.2.2.l
Neutral
current
earth
fault
detector
The
criterion
for
the
highest
setting
is:
- The
earth
fault
detector
must
pick
up
for
all
earth
faults
in
grounded
systems,
respectively
all
cross-country
faults
in
ungrounded
or
impedance
grounded
systems
which
lie
within
the
set
reach
of
the
underimpedance
units.
The
criterion
for
the
lowest
setting
is:
-
The
earth
fault
detector
may
not
pick
up
for
an
earth
fault
on
a
single
conductor
of
an
ungrounded
or
impdance
grounded
system.
-
The
earth
fault
detector
may
not
pick
up
during
heavy
phase
faults
due
to
spurious
neutral
currents
caused
by
c.t.
errors.
A
typically
recommended
value
is
I,r
(standard
version
of
the
LZ91:
I,r/IN
0.8
to
1.0
x
IN
for
LZ92
and
LZ92-l
0.
5)
If
there
is
no
setting
which
satisfies
both
these
limits,
a
neutral
voltage
polarising
ancillary
must
be
added
to
operate
in
conjunction
with
the
neutral
current
element:
-
This
is
available
as
a
separate
voltage
relay
to
be
inserted
into
the
equipment
rack
of
the
distance
relay.
7
-
Either
an
OR
or
an
AND
interlocking
logic
can
be
used
(see
parts
of
the
ordering
code
headed
EKl
or
EK2
in
the
tables
of
features
Table
9
.17,
Table
9.18
and
also
Fig.
9.25).
The
LED
signal
labelled
"E"
will
only
light
up
when
both
the
earth
fault
detector
and
at
least
one
underimpedance
phase
element
have
picked
up.
3.2.2.2
Reach
of
the
underimpedance
elements
8
standard
characteristic
The
standard
under
impedance
starting
characteristic
is
a
circle
with
its
centre
at
the
origin
of
the
impedance
plane.
The
relationships
for
an
earth
fault
R-0
are:
-
ULiR
-
Ul:R
-
·goo
--
UR
-
2
X
eJ
IR
A
-
j90
-
u +
2
XBe
IR
R
XA
=
XB
replica
reactance
in
forward
direction
replica
reactance
in
backward
direction
Criterion
for
pick-up:
u:R
j_
The
reach
for
radial
lines
and
the
different
kinds
of
faults
is:
-
phase-to-phase
fault:
same
as
setting
-
three-phase
fault
-
earth
fault
2
: x
setting
13
2
1 + k
oL
x
setting
(k = K
of
the
line)
oL o
ABB
has
a
computer
programme
for
checking
the
relay
settings
for
all
kinds
of
faults
and
fault
locations
where
complex
system
conditions
prevail.
The
starters
must
reliably
pick
up
for
a
fault
at
the
end
of
the
next
section
of
line
(back-up
zone).
Where
the
back-up
zone
is
not
being
taken
specifically
into
account,
the
setting
must
be
at
least
1.
3
times
the
impedance
of
the
protected
line.
The
influence
of
arc
resistance
must
also
be
considered
in
the
case
of
short
lines.
-
The
considerable
increase
of
load
current
which
can
occur
on
the
healthy
line
when
one
line
of
a
double
circuit
is
tripped
must
be
taken
into
account.
-
Balancing
currents
I
in
the
heal
thy
phases
during
an
earth
fault
must
not
cause
their
sta~ters
to
pick
up.
The
corresponding
limit
can
be
determined
as
follows:
1
B
max
·90°
2
X9
(IA+
19
max)
e J
Us
j900
-
-
XAe
-
2Is
-
'90°
U.t:.
A -
x
eJ
A
-
-
'90°
U.z.
.~
+ XBej90o
A +
X
eJ
B
-
2I
8
Fig.
3.2
-
Example
for
XA
f
XB
IA
I
Bmax
balancing
current
max.
load
current
replica
voltage
'90
I )
eJ
(S
phase)
Bmax
criterion
-
I_..
for
pick-up:
u.1
-L
Ur
--
·-+
'90°
--
u6
=
us
-
2
X
eJ
IS
A
·-
--
'90°
-
U,c:
us
+
2
X e
1
IS
B
___,...
- Us
with
A=
---
2
r;
The
limits
can
be
expressed
mathematically
as
follows:
-
in
grounded
systems
u
z
(Ohm/Phase)
9
-
in
ungrounded
or
impedance
grounded
systems
z
where
u
v
2 I x
1,25
Bmax
(Ohm/Phase)
U
lowest
phase-to-neutral
voltage
of
the
healthy
phases
for
an
earth
fault
(U
=
0.85
x
min.
rated
voltage)
U
lowest
phase-to-phase
rated
voltage
v
1.25
safety
factor
3.2.2.3
Special
underimpedance
starting
characteristics
10
If
it
is
impossible
to
satisfactorily
set
the
reach
according
to
Section
3.2.2.2,
then
the
following
procedure
should
be
tried.
The
influence
of
the
balancing
currents
must
be
carefully
analysed.
For
examining
the
S
phase
equations
for
an
R-0
earth
fault
see
Section
3.2.2.2.
The
relationship
XB/XA
may
be
changed
and
the
forward
reach
and
the
backward
reach
become
different.
The
origin
of
the
circular
characteristic
is
shifted
in
the
X-
direction.
( .
,,
A
I
B
The
diameter
of
circular
loci
of
the
pick-up
point
P
is
AB.
Fig.
3.3
-
Circular
underimpedance
starting
characteristic
The
angle
0
is
depending
on
the
network
conditions.
With
the
aid
of
computer
calculations
D was
found
to
be
2,
30°.
It
is
possible
to
change
the
angle.,C
from
90°
to
108°,
in
which
case
the
characteristic
is
no
longer
a
circle
(see
Fig.
3.4).
A
y
1
my
8
Fig.
3.4
-
Special
characteristic
o(
= 90°
or
108°
m
off-setting
factor
=
XB/XA
y =
permissible
setting
related
to
a
concentric
circle
11
12
Settings
t(O]
OU
0
J
m
'j
0
•••
90
90
1
1
30
90
0,57
1,04
30
108
1
1,18
(90)
(108)
(1)
(1,38)
30
108
0,57
1,22
Table
3.5
-
Permissible
settings
in
relation
to
a
circular
characteristic
Such
characteristics
have
a
considerably
extended
reactive
reach
compared
with
a
circle
concentric
to
the
origin.
The
equation
for
a
solidly
grounded
system
then
becomes:
u x y
=
where
1 + k
n =
----
0
-
for
starting
(Z///
..•
I
in
the
order
number)
2
-
It_J,s
pe~miss~ble
to
use
the
algebraic
sum
instead
of
the
geometric
sum (IA
+
IL),
since
it
represents
the
worst
case.
U
min.
phase-to-neutral
voltage
=
0.85
UB
.
(0.85
x
min.
rated
voltage)
min
The
effective
reach
along
the
line
is
dependent
on
the
characteristic
angle
of
the
line
and
the
kind
of
fault
(see
•rables
3.6
to
3.8):
-
-
Line
Characteristic
angle
Circle
Circle
Lense Lense
<pL
[ 0 ]
x = x
B A
XB
=
0.57
XA
x = x
B A
XB
=
0.57
XA
90
1
1
1 1
80
1 1
0.94
0.94
70
1
0.99
0.89
0.88
60
1
0.97
0.85
0.82
50
1
0.94
0.81
0.76
40
1
0.91
0.78
0.70
30
1
0.87
0.76
0.66
20
1
0.83
0.74
0.61
10
1
0.79
0.73
0.59
0
1
0.76 0.73
0.55
Lens:
ol
=
108°
(
Table
3.6
-
Relative
reach
in
relation
to
characteristic
and
line
angle
for
(."'
a
phase-to-phase
fault
Line
angle
90
80
70
60
50
40
30
20
10
0
1.15
1.15
1.15
1.15
1.15
1.15
1.15
1.15
1.15
1.15
Characteristic
Circle
XB
0,57
XA
1.11
1.08
1.04
1
0.94
0.92
0.87
0.83
0.79
0.75
0.98
0.94
0.89
0.88
0.85
0.84
0.84
0.83
0.85
0.88
Lense
XB
=
0,57
XA
0.95
0.88
0.82
0.76
0.72
0.67
0.64
0.61
0.59
0.58
Table
3.7
-
Relative
reach
in
relation
to
characteristic
and
line
angle
for
a
three-phase
fault
Line
angle
<p
[
0]
L
--
90
80
70
60
50
40
30
20
10
0
,__
(referred
to
the
reach
of
a
circle
about
the
origin
for
a
phase-to-phase
fault)
Characteristic
Circle Circle
Lense
Lense
XB
=
XA
XB
=
0,57
XA
XB
=
XA
XB
=
0,57
XA
-
-
1.15
1.11
0.98
0.95
1.15
1.08
1.0
0.94
1.15
1.06
1.0
0.93
1.15
1.04
1.03
0.93
1.15
1.02
1.05
0.95
1.15
1.01 1.08
0.97
1.15
1.0
1.11
0.98
1.15
1.0
1.12
1.0
1.15
1.0
1.16
1.02
1.15
1.0
1.21
1.05
·-
Table
3.8
-
Relative
reach
in
relation
to
characteristic
and
line
angle
for
a
three-phase
fault
(referred
to
the
reach
of
the
same
characteristic
for
a
phase-to-phase
fault)
13
Reverse
reach
The
effective
forwards
(XA)
and
reverse
(XB)
reaches
can
be
entered
in
the
diagram
of
Fig.
3.
2.
The
ratio
XB/XA
is
set
on
PCB
3
by
inserting
the
appropriate
value
for
resistor
Wi4
from
0.26
to
3.91
(Z./0.26/
to
/Z.3.91/
in
the
ordering
code,
see
Fig.
9.26).
Extreme
forwards
reaches
Values
of
XB/X
greater
than
1
are
of
consequence
when
an
extreme
forwards
reach
is
needefr.
This
is
achieved
by
reversing
the
primary
current
connec-
tions
to
the
distance
relay
and
then
reversing
the
measuring
direction
of
the
distance
unit
(using
switch
Sb
on
PCB
8,
order
number
HESG
439
686,
respectively
switch
I~
on
the
front
of
PCB
8,
HESG
440
718).
The
forwards
reach
then
corresponds
to
the
frontplate
setting
multiplied
by
the
set
ratio
XB/XA.
The
pick-up
criterion
in
the
diagram
of
Fig.
3.2
is
no
longer
determined
by
U,1
..L
u;,
but
instead
by
<f
(~,
lJi)
=
108°.
The
change
is
made
with
the
aid
of
the
soldered
link
LB3
on
PCB
3
(see
Fig.
9.26).
The
reach
for
earth
faults
corresponds
to
the
frontplate
setting
providing
the
k
factor
for
the
starting
units
matches
that
of
the
line
(k
= k
L).
The
s<Earter
k
is
set
using
resistor
Wi5
on
PCB
2
in
KZ91
or
K~~l-1
~see
0
Fig.
9.25).
The
above
changes
may
be
used
singly
or
in
conjunction
with
each
other!
3.3
k
factor
for
the
distance
measuring
system
-0
14
The
compensation
of
the
zero-sequence
impedance
is
calculated
from
the
positive-
sequence
impedance
ZL
and
zero-sequence
impedance
Z
of
the
line
or
cable.
oL
1
3
This
zero-sequence
compensation
factor
k
is
set
on
the
front
of
the
EW91
0
(according
to
HESG
438
454)
as
follows:
EW91
code
K.0:
Only
the
magnitude
of
(lk
I>
is
set.
This
is
generally
all
t.ha~
is
necessary
in
the
case
of
overhead
lines
(thumbwheel
switch
'Pk
set
to
zero).
0
EW91
code
K.1:
Both
the
magnitude
Clk
I)
and
phase-angle
('Pk )
are
set,
which
is
of
consequence
abov~
all
in
cable
systems.
0
It
is
always
possible
to
set
the
magnitude
and
phase-angle
in
the
case
of
the
input
transformer
unit
according
to
HESG
440 754
(see
Section
3.12).
The
k
factor
only
bears
an
influence
on
the
distance
measuring
system.
0
3.4
Impedance
settings
of
the
various
zones
3.4.1
Determining
the
reaches
of
the
distance
zones
In
order
to
calculate
the
settings
the
fault
impedances
and
the
phase-angles
of
the
sections
of
line
to
be
protected
must
be
known.
Z3
=
0,
BS
(a+
k ·
b2
l .
i-----
Z2
=
0,
85
(a
+ k ·
b1
l
-
-
b2
-
Z1
=0,85·0
-
I
-
~·--
Zus
= 1,2
I
b1
·a
I
A
-
a
-
b
-
B
(
Fig.
3.9
-
Reaches
of
the
various
distance
zones
a,
b
2
us
zone
impedances
infeed
factor
which
takes
into
account
an
intermediate
infeed
and
the
consequential
apparent
increase
in
the
impedance
by
the
relay
corresponding
line
impedances
overreach
zone
impedance
Zus
=
1.5
z
1
15
A
1
2
3
B
IA+
I B
4 -
(
0
Fig.
3.10
-
Exampel
for
the
calcuation
of
k;
k
where
check
the
overreach
for
k > 1
in
the
event
that
the
source
for
B
is
out
of
operation:
IA
+
IB
::::.
1
max.
possible
fault
current
min.
possible
fault
current
distance
relays
3.4.2
Determining
the
settings
m.
and
N.
1. 1.
16
z
Ls
where
ZLp
ZL
=--p-
-=:u_
rI
rz
primary
line
impedance
secondary
line
impedance
main
p.t.
ratio
main
c.
t.
ratio
impedance
ratio
The
secondary
resistance
and
reactance
values
are
calculated
in
the
same
manner.
Calculating
X.
-------------:'.!:
Before
the
values
m.
and
N.
can
be
set
on
the
main
processing
unit
it
is
necessary
to
calculal:e
the
feactances
X
..
These
are
not
exactly
equal
to
the
line
reactances
XL
(line
impedance
Z
=\
+
jXL),
because
of
the
inclination
of
the
relay
reactance
characteristi~
by
~he
angle
cl.
.
jX
R
x
=1
R
/X
=2
R
Fig.
3.11
-
Line
impedance
z
entered
in
the
relay
characteristic
L
Thus
to
obtain
the
reactances
X.,
the
line
reactances
have
to
be
corrected
by
l.
the
factor
kx:
The
correction
factor
kx
is
given
by:
tan
a
k
=l+"---
x
tan
<f>
If
the
phase-angle
V(_
is
less
than
40°,
as
can
be
the
case
in
cable
systems,
there
are
two
possibilities
for
grading
as
follows:
grading
in
relation
to
XL
grading
in
relation
to
RL
Grading
with
XL:
If
the
setting
R/X
is
greater
than
1,
e.g.
R/X
kx
according
to
the
table
3.12
is
used.
2
(see
Fig.
3.11),
then
the
factor
Grading
with
RL:
If
the
setting
of
the
polygon
is
made
in
relation
to
the
line
resistance
RL
with
the
arch
resistance
compensation
R/X = 1
(see
Section
3.5),
then
RLi
is
used
instead
of
XLi
and
kR
instead
of
kx
for
grading
(see
Table
3.12).
Where
for
ii
L <
40°:
Xi
=
kR
. RLi ;
with
kR
= 1 tancc'. .
tan
'f
17
18
Line
angle
R/X
=
I
R/X
=
2
sPL
( 0 )
_kx
k
R
kx
0
-
I
-
5
-
0,992
-
10
-
0,985
-
15
-
0,977
-
20
-
0,968
-
21
-
0,966
1,228
25
-
0,959
1,188
30
-
0,95
1,152
35
-
0,939
1,125
40
1,104
0,927
1,104
45
1,087
-
1,087
50
1,073
-
1,073
55
1,061
-
1,061
60
1,05
-
1,05
65
1,041
-
1,041
70
1,032
-
1,032
75
1,023
-
1,023
80
1,015
-
1,015
85
1,
008.
-
1,008
90
1
-
1
Table
3.12
-
Factors
kx
and
kR
in
relation
to
'P
(a=
5°)
System
voltage
P.
t.
ratio
C.t.
ratio
Primary
zone
impedances
Phase-angle
of
line
Relay
ratings
Reactance
line
slope
u
=
KU
KI
=
ZLpl
=
<p
IN
a
60
kV
(60
kV I
{J)
I
(110
v I
{3)
200
A I 5 A
40
4 Ohm,
ZLp2
=
6 Ohm,
z =
Lp3
60°
5
A,
UN
110
v
50
545.45
8
Ohm
Firstly
the
secondary
reactances
must
be
calculated
from
the
primary
values:
ii
I
X .
x--and
Lp
..
uu
The
line
reactances
for
the
three
zones
become:
XLl
=
0.254
Ohm,
XL
2
0.381
Ohm,
xL
3
=
0.508
Ohm
The
correct.ion
factor
kx
is:
tan
1 + =
1.05
tan
60°
(
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ABB Modures LZ91 Instructions For Installation And Operation Manual

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